unsupported/test/cxx11_tensor_contraction.cpp - manifest_repos/eigen - Git at Google

 // This file is part of Eigen, a lightweight C++ template library
 // for linear algebra.
 //
 // Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com>
 //
 // This Source Code Form is subject to the terms of the Mozilla
 // Public License v. 2.0. If a copy of the MPL was not distributed
 // with this file, You can obtain one at http://mozilla.org/MPL/2.0/.

 #include "main.h"

 #include <Eigen/CXX11/Tensor>

 using Eigen::DefaultDevice;
 using Eigen::Tensor;

 typedef Tensor<float, 1>::DimensionPair DimPair;

 template<int DataLayout>
 static void test_evals()
 {
   Tensor<float, 2, DataLayout> mat1(2, 3);
   Tensor<float, 2, DataLayout> mat2(2, 3);
   Tensor<float, 2, DataLayout> mat3(3, 2);

   mat1.setRandom();
   mat2.setRandom();
   mat3.setRandom();

   Tensor<float, 2, DataLayout> mat4(3,3);
   mat4.setZero();
   Eigen::array<DimPair, 1> dims3 = {{DimPair(0, 0)}};
   typedef TensorEvaluator<decltype(mat1.contract(mat2, dims3)), DefaultDevice> Evaluator;
   Evaluator eval(mat1.contract(mat2, dims3), DefaultDevice());
   eval.evalTo(mat4.data());
   EIGEN_STATIC_ASSERT(Evaluator::NumDims==2ul, YOU_MADE_A_PROGRAMMING_MISTAKE);
   VERIFY_IS_EQUAL(eval.dimensions()[0], 3);
   VERIFY_IS_EQUAL(eval.dimensions()[1], 3);

   VERIFY_IS_APPROX(mat4(0,0), mat1(0,0)*mat2(0,0) + mat1(1,0)*mat2(1,0));
   VERIFY_IS_APPROX(mat4(0,1), mat1(0,0)*mat2(0,1) + mat1(1,0)*mat2(1,1));
   VERIFY_IS_APPROX(mat4(0,2), mat1(0,0)*mat2(0,2) + mat1(1,0)*mat2(1,2));
   VERIFY_IS_APPROX(mat4(1,0), mat1(0,1)*mat2(0,0) + mat1(1,1)*mat2(1,0));
   VERIFY_IS_APPROX(mat4(1,1), mat1(0,1)*mat2(0,1) + mat1(1,1)*mat2(1,1));
   VERIFY_IS_APPROX(mat4(1,2), mat1(0,1)*mat2(0,2) + mat1(1,1)*mat2(1,2));
   VERIFY_IS_APPROX(mat4(2,0), mat1(0,2)*mat2(0,0) + mat1(1,2)*mat2(1,0));
   VERIFY_IS_APPROX(mat4(2,1), mat1(0,2)*mat2(0,1) + mat1(1,2)*mat2(1,1));
   VERIFY_IS_APPROX(mat4(2,2), mat1(0,2)*mat2(0,2) + mat1(1,2)*mat2(1,2));

   Tensor<float, 2, DataLayout> mat5(2,2);
   mat5.setZero();
   Eigen::array<DimPair, 1> dims4 = {{DimPair(1, 1)}};
   typedef TensorEvaluator<decltype(mat1.contract(mat2, dims4)), DefaultDevice> Evaluator2;
   Evaluator2 eval2(mat1.contract(mat2, dims4), DefaultDevice());
   eval2.evalTo(mat5.data());
   EIGEN_STATIC_ASSERT(Evaluator2::NumDims==2ul, YOU_MADE_A_PROGRAMMING_MISTAKE);
   VERIFY_IS_EQUAL(eval2.dimensions()[0], 2);
   VERIFY_IS_EQUAL(eval2.dimensions()[1], 2);

   VERIFY_IS_APPROX(mat5(0,0), mat1(0,0)*mat2(0,0) + mat1(0,1)*mat2(0,1) + mat1(0,2)*mat2(0,2));
   VERIFY_IS_APPROX(mat5(0,1), mat1(0,0)*mat2(1,0) + mat1(0,1)*mat2(1,1) + mat1(0,2)*mat2(1,2));
   VERIFY_IS_APPROX(mat5(1,0), mat1(1,0)*mat2(0,0) + mat1(1,1)*mat2(0,1) + mat1(1,2)*mat2(0,2));
   VERIFY_IS_APPROX(mat5(1,1), mat1(1,0)*mat2(1,0) + mat1(1,1)*mat2(1,1) + mat1(1,2)*mat2(1,2));

   Tensor<float, 2, DataLayout> mat6(2,2);
   mat6.setZero();
   Eigen::array<DimPair, 1> dims6 = {{DimPair(1, 0)}};
   typedef TensorEvaluator<decltype(mat1.contract(mat3, dims6)), DefaultDevice> Evaluator3;
   Evaluator3 eval3(mat1.contract(mat3, dims6), DefaultDevice());
   eval3.evalTo(mat6.data());
   EIGEN_STATIC_ASSERT(Evaluator3::NumDims==2ul, YOU_MADE_A_PROGRAMMING_MISTAKE);
   VERIFY_IS_EQUAL(eval3.dimensions()[0], 2);
   VERIFY_IS_EQUAL(eval3.dimensions()[1], 2);

   VERIFY_IS_APPROX(mat6(0,0), mat1(0,0)*mat3(0,0) + mat1(0,1)*mat3(1,0) + mat1(0,2)*mat3(2,0));
   VERIFY_IS_APPROX(mat6(0,1), mat1(0,0)*mat3(0,1) + mat1(0,1)*mat3(1,1) + mat1(0,2)*mat3(2,1));
   VERIFY_IS_APPROX(mat6(1,0), mat1(1,0)*mat3(0,0) + mat1(1,1)*mat3(1,0) + mat1(1,2)*mat3(2,0));
   VERIFY_IS_APPROX(mat6(1,1), mat1(1,0)*mat3(0,1) + mat1(1,1)*mat3(1,1) + mat1(1,2)*mat3(2,1));
 }

 template<int DataLayout>
 static void test_scalar()
 {
   Tensor<float, 1, DataLayout> vec1({6});
   Tensor<float, 1, DataLayout> vec2({6});

   vec1.setRandom();
   vec2.setRandom();

   Eigen::array<DimPair, 1> dims = {{DimPair(0, 0)}};
   Tensor<float, 0, DataLayout> scalar = vec1.contract(vec2, dims);

   float expected = 0.0f;
   for (int i = 0; i < 6; ++i) {
     expected += vec1(i) * vec2(i);
   }
   VERIFY_IS_APPROX(scalar(), expected);
 }

 template<int DataLayout>
 static void test_multidims()
 {
   Tensor<float, 3, DataLayout> mat1(2, 2, 2);
   Tensor<float, 4, DataLayout> mat2(2, 2, 2, 2);

   mat1.setRandom();
   mat2.setRandom();

   Tensor<float, 3, DataLayout> mat3(2, 2, 2);
   mat3.setZero();
   Eigen::array<DimPair, 2> dims = {{DimPair(1, 2), DimPair(2, 3)}};
   typedef TensorEvaluator<decltype(mat1.contract(mat2, dims)), DefaultDevice> Evaluator;
   Evaluator eval(mat1.contract(mat2, dims), DefaultDevice());
   eval.evalTo(mat3.data());
   EIGEN_STATIC_ASSERT(Evaluator::NumDims==3ul, YOU_MADE_A_PROGRAMMING_MISTAKE);
   VERIFY_IS_EQUAL(eval.dimensions()[0], 2);
   VERIFY_IS_EQUAL(eval.dimensions()[1], 2);
   VERIFY_IS_EQUAL(eval.dimensions()[2], 2);

   VERIFY_IS_APPROX(mat3(0,0,0), mat1(0,0,0)*mat2(0,0,0,0) + mat1(0,1,0)*mat2(0,0,1,0) +
                                 mat1(0,0,1)*mat2(0,0,0,1) + mat1(0,1,1)*mat2(0,0,1,1));
   VERIFY_IS_APPROX(mat3(0,0,1), mat1(0,0,0)*mat2(0,1,0,0) + mat1(0,1,0)*mat2(0,1,1,0) +
                                 mat1(0,0,1)*mat2(0,1,0,1) + mat1(0,1,1)*mat2(0,1,1,1));
   VERIFY_IS_APPROX(mat3(0,1,0), mat1(0,0,0)*mat2(1,0,0,0) + mat1(0,1,0)*mat2(1,0,1,0) +
                                 mat1(0,0,1)*mat2(1,0,0,1) + mat1(0,1,1)*mat2(1,0,1,1));
   VERIFY_IS_APPROX(mat3(0,1,1), mat1(0,0,0)*mat2(1,1,0,0) + mat1(0,1,0)*mat2(1,1,1,0) +
                                 mat1(0,0,1)*mat2(1,1,0,1) + mat1(0,1,1)*mat2(1,1,1,1));
   VERIFY_IS_APPROX(mat3(1,0,0), mat1(1,0,0)*mat2(0,0,0,0) + mat1(1,1,0)*mat2(0,0,1,0) +
                                 mat1(1,0,1)*mat2(0,0,0,1) + mat1(1,1,1)*mat2(0,0,1,1));
   VERIFY_IS_APPROX(mat3(1,0,1), mat1(1,0,0)*mat2(0,1,0,0) + mat1(1,1,0)*mat2(0,1,1,0) +
                                 mat1(1,0,1)*mat2(0,1,0,1) + mat1(1,1,1)*mat2(0,1,1,1));
   VERIFY_IS_APPROX(mat3(1,1,0), mat1(1,0,0)*mat2(1,0,0,0) + mat1(1,1,0)*mat2(1,0,1,0) +
                                 mat1(1,0,1)*mat2(1,0,0,1) + mat1(1,1,1)*mat2(1,0,1,1));
   VERIFY_IS_APPROX(mat3(1,1,1), mat1(1,0,0)*mat2(1,1,0,0) + mat1(1,1,0)*mat2(1,1,1,0) +
                                 mat1(1,0,1)*mat2(1,1,0,1) + mat1(1,1,1)*mat2(1,1,1,1));

   Tensor<float, 2, DataLayout> mat4(2, 2);
   Tensor<float, 3, DataLayout> mat5(2, 2, 2);

   mat4.setRandom();
   mat5.setRandom();

   Tensor<float, 1, DataLayout> mat6(2);
   mat6.setZero();
   Eigen::array<DimPair, 2> dims2({{DimPair(0, 1), DimPair(1, 0)}});
   typedef TensorEvaluator<decltype(mat4.contract(mat5, dims2)), DefaultDevice> Evaluator2;
   Evaluator2 eval2(mat4.contract(mat5, dims2), DefaultDevice());
   eval2.evalTo(mat6.data());
   EIGEN_STATIC_ASSERT(Evaluator2::NumDims==1ul, YOU_MADE_A_PROGRAMMING_MISTAKE);
   VERIFY_IS_EQUAL(eval2.dimensions()[0], 2);

   VERIFY_IS_APPROX(mat6(0), mat4(0,0)*mat5(0,0,0) + mat4(1,0)*mat5(0,1,0) +
                    mat4(0,1)*mat5(1,0,0) + mat4(1,1)*mat5(1,1,0));
   VERIFY_IS_APPROX(mat6(1), mat4(0,0)*mat5(0,0,1) + mat4(1,0)*mat5(0,1,1) +
                    mat4(0,1)*mat5(1,0,1) + mat4(1,1)*mat5(1,1,1));
 }

 template<int DataLayout>
 static void test_holes() {
   Tensor<float, 4, DataLayout> t1(2, 5, 7, 3);
   Tensor<float, 5, DataLayout> t2(2, 7, 11, 13, 3);
   t1.setRandom();
   t2.setRandom();

   Eigen::array<DimPair, 2> dims = {{DimPair(0, 0), DimPair(3, 4)}};
   Tensor<float, 5, DataLayout> result = t1.contract(t2, dims);
   VERIFY_IS_EQUAL(result.dimension(0), 5);
   VERIFY_IS_EQUAL(result.dimension(1), 7);
   VERIFY_IS_EQUAL(result.dimension(2), 7);
   VERIFY_IS_EQUAL(result.dimension(3), 11);
   VERIFY_IS_EQUAL(result.dimension(4), 13);

   for (int i = 0; i < 5; ++i) {
     for (int j = 0; j < 5; ++j) {
       for (int k = 0; k < 5; ++k) {
         for (int l = 0; l < 5; ++l) {
           for (int m = 0; m < 5; ++m) {
             VERIFY_IS_APPROX(result(i, j, k, l, m),
                              t1(0, i, j, 0) * t2(0, k, l, m, 0) +
                              t1(1, i, j, 0) * t2(1, k, l, m, 0) +
                              t1(0, i, j, 1) * t2(0, k, l, m, 1) +
                              t1(1, i, j, 1) * t2(1, k, l, m, 1) +
                              t1(0, i, j, 2) * t2(0, k, l, m, 2) +
                              t1(1, i, j, 2) * t2(1, k, l, m, 2));
           }
         }
       }
     }
   }
 }

 template<int DataLayout>
 static void test_full_redux()
 {
   Tensor<float, 2, DataLayout> t1(2, 2);
   Tensor<float, 3, DataLayout> t2(2, 2, 2);
   t1.setRandom();
   t2.setRandom();

   Eigen::array<DimPair, 2> dims = {{DimPair(0, 0), DimPair(1, 1)}};
   Tensor<float, 1, DataLayout> result = t1.contract(t2, dims);
   VERIFY_IS_EQUAL(result.dimension(0), 2);
   VERIFY_IS_APPROX(result(0), t1(0, 0) * t2(0, 0, 0) +  t1(1, 0) * t2(1, 0, 0)
                             + t1(0, 1) * t2(0, 1, 0) +  t1(1, 1) * t2(1, 1, 0));
   VERIFY_IS_APPROX(result(1), t1(0, 0) * t2(0, 0, 1) +  t1(1, 0) * t2(1, 0, 1)
                             + t1(0, 1) * t2(0, 1, 1) +  t1(1, 1) * t2(1, 1, 1));

   dims[0] = DimPair(1, 0);
   dims[1] = DimPair(2, 1);
   result = t2.contract(t1, dims);
   VERIFY_IS_EQUAL(result.dimension(0), 2);
   VERIFY_IS_APPROX(result(0), t1(0, 0) * t2(0, 0, 0) +  t1(1, 0) * t2(0, 1, 0)
                             + t1(0, 1) * t2(0, 0, 1) +  t1(1, 1) * t2(0, 1, 1));
   VERIFY_IS_APPROX(result(1), t1(0, 0) * t2(1, 0, 0) +  t1(1, 0) * t2(1, 1, 0)
                             + t1(0, 1) * t2(1, 0, 1) +  t1(1, 1) * t2(1, 1, 1));
 }

 template<int DataLayout>
 static void test_contraction_of_contraction()
 {
   Tensor<float, 2, DataLayout> t1(2, 2);
   Tensor<float, 2, DataLayout> t2(2, 2);
   Tensor<float, 2, DataLayout> t3(2, 2);
   Tensor<float, 2, DataLayout> t4(2, 2);
   t1.setRandom();
   t2.setRandom();
   t3.setRandom();
   t4.setRandom();

   Eigen::array<DimPair, 1> dims = {{DimPair(1, 0)}};
   auto contract1 = t1.contract(t2, dims);
   auto diff = t3 - contract1;
   auto contract2 = t1.contract(t4, dims);
   Tensor<float, 2, DataLayout> result = contract2.contract(diff, dims);

   VERIFY_IS_EQUAL(result.dimension(0), 2);
   VERIFY_IS_EQUAL(result.dimension(1), 2);

   Eigen::Map<Eigen::Matrix<float, Dynamic, Dynamic, DataLayout>>
       m1(t1.data(), 2, 2), m2(t2.data(), 2, 2), m3(t3.data(), 2, 2),
       m4(t4.data(), 2, 2);
   Eigen::Matrix<float, Dynamic, Dynamic, DataLayout>
       expected = (m1 * m4) * (m3 - m1 * m2);

   VERIFY_IS_APPROX(result(0, 0), expected(0, 0));
   VERIFY_IS_APPROX(result(0, 1), expected(0, 1));
   VERIFY_IS_APPROX(result(1, 0), expected(1, 0));
   VERIFY_IS_APPROX(result(1, 1), expected(1, 1));
 }

 template<int DataLayout>
 static void test_expr()
 {
   Tensor<float, 2, DataLayout> mat1(2, 3);
   Tensor<float, 2, DataLayout> mat2(3, 2);
   mat1.setRandom();
   mat2.setRandom();

   Tensor<float, 2, DataLayout> mat3(2,2);

   Eigen::array<DimPair, 1> dims = {{DimPair(1, 0)}};
   mat3 = mat1.contract(mat2, dims);

   VERIFY_IS_APPROX(mat3(0,0), mat1(0,0)*mat2(0,0) + mat1(0,1)*mat2(1,0) + mat1(0,2)*mat2(2,0));
   VERIFY_IS_APPROX(mat3(0,1), mat1(0,0)*mat2(0,1) + mat1(0,1)*mat2(1,1) + mat1(0,2)*mat2(2,1));
   VERIFY_IS_APPROX(mat3(1,0), mat1(1,0)*mat2(0,0) + mat1(1,1)*mat2(1,0) + mat1(1,2)*mat2(2,0));
   VERIFY_IS_APPROX(mat3(1,1), mat1(1,0)*mat2(0,1) + mat1(1,1)*mat2(1,1) + mat1(1,2)*mat2(2,1));
 }

 template<int DataLayout>
 static void test_out_of_order_contraction()
 {
   Tensor<float, 3, DataLayout> mat1(2, 2, 2);
   Tensor<float, 3, DataLayout> mat2(2, 2, 2);

   mat1.setRandom();
   mat2.setRandom();

   Tensor<float, 2, DataLayout> mat3(2, 2);

   Eigen::array<DimPair, 2> dims = {{DimPair(2, 0), DimPair(0, 2)}};
   mat3 = mat1.contract(mat2, dims);

   VERIFY_IS_APPROX(mat3(0, 0),
                    mat1(0,0,0)*mat2(0,0,0) + mat1(1,0,0)*mat2(0,0,1) +
                    mat1(0,0,1)*mat2(1,0,0) + mat1(1,0,1)*mat2(1,0,1));
   VERIFY_IS_APPROX(mat3(1, 0),
                    mat1(0,1,0)*mat2(0,0,0) + mat1(1,1,0)*mat2(0,0,1) +
                    mat1(0,1,1)*mat2(1,0,0) + mat1(1,1,1)*mat2(1,0,1));
   VERIFY_IS_APPROX(mat3(0, 1),
                    mat1(0,0,0)*mat2(0,1,0) + mat1(1,0,0)*mat2(0,1,1) +
                    mat1(0,0,1)*mat2(1,1,0) + mat1(1,0,1)*mat2(1,1,1));
   VERIFY_IS_APPROX(mat3(1, 1),
                    mat1(0,1,0)*mat2(0,1,0) + mat1(1,1,0)*mat2(0,1,1) +
                    mat1(0,1,1)*mat2(1,1,0) + mat1(1,1,1)*mat2(1,1,1));

   Eigen::array<DimPair, 2> dims2 = {{DimPair(0, 2), DimPair(2, 0)}};
   mat3 = mat1.contract(mat2, dims2);

   VERIFY_IS_APPROX(mat3(0, 0),
                    mat1(0,0,0)*mat2(0,0,0) + mat1(1,0,0)*mat2(0,0,1) +
                    mat1(0,0,1)*mat2(1,0,0) + mat1(1,0,1)*mat2(1,0,1));
   VERIFY_IS_APPROX(mat3(1, 0),
                    mat1(0,1,0)*mat2(0,0,0) + mat1(1,1,0)*mat2(0,0,1) +
                    mat1(0,1,1)*mat2(1,0,0) + mat1(1,1,1)*mat2(1,0,1));
   VERIFY_IS_APPROX(mat3(0, 1),
                    mat1(0,0,0)*mat2(0,1,0) + mat1(1,0,0)*mat2(0,1,1) +
                    mat1(0,0,1)*mat2(1,1,0) + mat1(1,0,1)*mat2(1,1,1));
   VERIFY_IS_APPROX(mat3(1, 1),
                    mat1(0,1,0)*mat2(0,1,0) + mat1(1,1,0)*mat2(0,1,1) +
                    mat1(0,1,1)*mat2(1,1,0) + mat1(1,1,1)*mat2(1,1,1));

 }

 template<int DataLayout>
 static void test_consistency()
 {
   // this does something like testing (A*B)^T = (B^T * A^T)

   Tensor<float, 3, DataLayout> mat1(4, 3, 5);
   Tensor<float, 5, DataLayout> mat2(3, 2, 1, 5, 4);
   mat1.setRandom();
   mat2.setRandom();

   Tensor<float, 4, DataLayout> mat3(5, 2, 1, 5);
   Tensor<float, 4, DataLayout> mat4(2, 1, 5, 5);

   // contract on dimensions of size 4 and 3
   Eigen::array<DimPair, 2> dims1 = {{DimPair(0, 4), DimPair(1, 0)}};
   Eigen::array<DimPair, 2> dims2 = {{DimPair(4, 0), DimPair(0, 1)}};

   mat3 = mat1.contract(mat2, dims1);
   mat4 = mat2.contract(mat1, dims2);

   // check that these are equal except for ordering of dimensions
   if (DataLayout == ColMajor) {
     for (size_t i = 0; i < 5; i++) {
       for (size_t j = 0; j < 10; j++) {
         VERIFY_IS_APPROX(mat3.data()[i + 5 * j], mat4.data()[j + 10 * i]);
       }
     }
   } else {
     // Row major
     for (size_t i = 0; i < 5; i++) {
       for (size_t j = 0; j < 10; j++) {
         VERIFY_IS_APPROX(mat3.data()[10 * i + j], mat4.data()[i + 5 * j]);
       }
     }
   }
 }

 template<int DataLayout>
 static void test_large_contraction()
 {
   Tensor<float, 4, DataLayout> t_left(30, 50, 8, 31);
   Tensor<float, 5, DataLayout> t_right(8, 31, 7, 20, 10);
   Tensor<float, 5, DataLayout> t_result(30, 50, 7, 20, 10);

   t_left.setRandom();
   t_right.setRandom();

   // Add a little offset so that the results won't be close to zero.
   t_left += t_left.constant(1.0f);
   t_right += t_right.constant(1.0f);

   typedef Map<Eigen::Matrix<float, Dynamic, Dynamic, DataLayout>> MapXf;
   MapXf m_left(t_left.data(), 1500, 248);
   MapXf m_right(t_right.data(), 248, 1400);
   Eigen::Matrix<float, Dynamic, Dynamic, DataLayout> m_result(1500, 1400);

   // this contraction should be equivalent to a single matrix multiplication
   Eigen::array<DimPair, 2> dims = {{DimPair(2, 0), DimPair(3, 1)}};

   // compute results by separate methods
   t_result = t_left.contract(t_right, dims);
   m_result = m_left * m_right;

   for (int i = 0; i < t_result.dimensions().TotalSize(); i++) {
     VERIFY(&t_result.data()[i] != &m_result.data()[i]);
     VERIFY_IS_APPROX(t_result.data()[i], m_result.data()[i]);
   }
 }

 template<int DataLayout>
 static void test_matrix_vector()
 {
   Tensor<float, 2, DataLayout> t_left(30, 50);
   Tensor<float, 1, DataLayout> t_right(50);
   Tensor<float, 1, DataLayout> t_result(30);

   t_left.setRandom();
   t_right.setRandom();

   typedef Map<Eigen::Matrix<float, Dynamic, Dynamic, DataLayout>> MapXf;
   MapXf m_left(t_left.data(), 30, 50);
   MapXf m_right(t_right.data(), 50, 1);
   Eigen::Matrix<float, Dynamic, Dynamic, DataLayout> m_result(30, 1);

   // this contraction should be equivalent to a single matrix multiplication
   Eigen::array<DimPair, 1> dims{{DimPair(1, 0)}};

   // compute results by separate methods
   t_result = t_left.contract(t_right, dims);
   m_result = m_left * m_right;

   for (int i = 0; i < t_result.dimensions().TotalSize(); i++) {
     VERIFY(internal::isApprox(t_result(i), m_result(i, 0), 1));
   }
 }


 template<int DataLayout>
 static void test_tensor_vector()
 {
   Tensor<float, 3, DataLayout> t_left(7, 13, 17);
   Tensor<float, 2, DataLayout> t_right(1, 7);

   t_left.setRandom();
   t_right.setRandom();

   typedef typename Tensor<float, 1, DataLayout>::DimensionPair DimensionPair;
   Eigen::array<DimensionPair, 1> dim_pair01{{{0, 1}}};
   Tensor<float, 3, DataLayout> t_result = t_left.contract(t_right, dim_pair01);

   typedef Map<Eigen::Matrix<float, Dynamic, Dynamic, DataLayout>> MapXf;
   MapXf m_left(t_left.data(), 7, 13*17);
   MapXf m_right(t_right.data(), 1, 7);
   Eigen::Matrix<float, Dynamic, Dynamic, DataLayout> m_result = m_left.transpose() * m_right.transpose();

   for (int i = 0; i < t_result.dimensions().TotalSize(); i++) {
     VERIFY(internal::isApprox(t_result(i), m_result(i, 0), 1));
   }
 }


 template<int DataLayout>
 static void test_small_blocking_factors()
 {
   Tensor<float, 4, DataLayout> t_left(30, 5, 3, 31);
   Tensor<float, 5, DataLayout> t_right(3, 31, 7, 20, 1);
   t_left.setRandom();
   t_right.setRandom();

   // Add a little offset so that the results won't be close to zero.
   t_left += t_left.constant(1.0f);
   t_right += t_right.constant(1.0f);

   // Force the cache sizes, which results in smaller blocking factors.
   Eigen::setCpuCacheSizes(896, 1920, 2944);

   // this contraction should be equivalent to a single matrix multiplication
   Eigen::array<DimPair, 2> dims = {{DimPair(2, 0), DimPair(3, 1)}};
   Tensor<float, 5, DataLayout> t_result;
   t_result = t_left.contract(t_right, dims);

   // compute result using a simple eigen matrix product
   Map<Eigen::Matrix<float, Dynamic, Dynamic, DataLayout>> m_left(t_left.data(), 150, 93);
   Map<Eigen::Matrix<float, Dynamic, Dynamic, DataLayout>> m_right(t_right.data(), 93, 140);
   Eigen::Matrix<float, Dynamic, Dynamic, DataLayout> m_result = m_left * m_right;

   for (int i = 0; i < t_result.dimensions().TotalSize(); i++) {
     VERIFY_IS_APPROX(t_result.data()[i], m_result.data()[i]);
   }
 }

 template<int DataLayout>
 static void test_tensor_product()
 {
   Tensor<float, 2, DataLayout> mat1(2, 3);
   Tensor<float, 2, DataLayout> mat2(4, 1);
   mat1.setRandom();
   mat2.setRandom();

   Tensor<float, 4, DataLayout> result = mat1.contract(mat2, Eigen::array<DimPair, 0>{{}});

   VERIFY_IS_EQUAL(result.dimension(0), 2);
   VERIFY_IS_EQUAL(result.dimension(1), 3);
   VERIFY_IS_EQUAL(result.dimension(2), 4);
   VERIFY_IS_EQUAL(result.dimension(3), 1);
   for (int i = 0; i < result.dimension(0); ++i) {
     for (int j = 0; j < result.dimension(1); ++j) {
       for (int k = 0; k < result.dimension(2); ++k) {
         for (int l = 0; l < result.dimension(3); ++l) {
 			VERIFY_IS_APPROX(result(i, j, k, l), mat1(i, j) * mat2(k, l) );
         }
       }
     }
   }
 }


 template<int DataLayout>
 static void test_const_inputs()
 {
   Tensor<float, 2, DataLayout> in1(2, 3);
   Tensor<float, 2, DataLayout> in2(3, 2);
   in1.setRandom();
   in2.setRandom();

   TensorMap<Tensor<const float, 2, DataLayout> > mat1(in1.data(), 2, 3);
   TensorMap<Tensor<const float, 2, DataLayout> > mat2(in2.data(), 3, 2);
   Tensor<float, 2, DataLayout> mat3(2,2);

   Eigen::array<DimPair, 1> dims = {{DimPair(1, 0)}};
   mat3 = mat1.contract(mat2, dims);

   VERIFY_IS_APPROX(mat3(0,0), mat1(0,0)*mat2(0,0) + mat1(0,1)*mat2(1,0) + mat1(0,2)*mat2(2,0));
   VERIFY_IS_APPROX(mat3(0,1), mat1(0,0)*mat2(0,1) + mat1(0,1)*mat2(1,1) + mat1(0,2)*mat2(2,1));
   VERIFY_IS_APPROX(mat3(1,0), mat1(1,0)*mat2(0,0) + mat1(1,1)*mat2(1,0) + mat1(1,2)*mat2(2,0));
   VERIFY_IS_APPROX(mat3(1,1), mat1(1,0)*mat2(0,1) + mat1(1,1)*mat2(1,1) + mat1(1,2)*mat2(2,1));
 }

 void test_cxx11_tensor_contraction()
 {
   CALL_SUBTEST(test_evals<ColMajor>());
   CALL_SUBTEST(test_evals<RowMajor>());
   CALL_SUBTEST(test_scalar<ColMajor>());
   CALL_SUBTEST(test_scalar<RowMajor>());
   CALL_SUBTEST(test_multidims<ColMajor>());
   CALL_SUBTEST(test_multidims<RowMajor>());
   CALL_SUBTEST(test_holes<ColMajor>());
   CALL_SUBTEST(test_holes<RowMajor>());
   CALL_SUBTEST(test_full_redux<ColMajor>());
   CALL_SUBTEST(test_full_redux<RowMajor>());
   CALL_SUBTEST(test_contraction_of_contraction<ColMajor>());
   CALL_SUBTEST(test_contraction_of_contraction<RowMajor>());
   CALL_SUBTEST(test_expr<ColMajor>());
   CALL_SUBTEST(test_expr<RowMajor>());
   CALL_SUBTEST(test_out_of_order_contraction<ColMajor>());
   CALL_SUBTEST(test_out_of_order_contraction<RowMajor>());
   CALL_SUBTEST(test_consistency<ColMajor>());
   CALL_SUBTEST(test_consistency<RowMajor>());
   CALL_SUBTEST(test_large_contraction<ColMajor>());
   CALL_SUBTEST(test_large_contraction<RowMajor>());
   CALL_SUBTEST(test_matrix_vector<ColMajor>());
   CALL_SUBTEST(test_matrix_vector<RowMajor>());
   CALL_SUBTEST(test_tensor_vector<ColMajor>());
   CALL_SUBTEST(test_tensor_vector<RowMajor>());
   CALL_SUBTEST(test_small_blocking_factors<ColMajor>());
   CALL_SUBTEST(test_small_blocking_factors<RowMajor>());
   CALL_SUBTEST(test_tensor_product<ColMajor>());
   CALL_SUBTEST(test_tensor_product<RowMajor>());
   CALL_SUBTEST(test_const_inputs<ColMajor>());
   CALL_SUBTEST(test_const_inputs<RowMajor>());
 }
	// This file is part of Eigen, a lightweight C++ template library
	// for linear algebra.
	//
	// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com>
	//
	// This Source Code Form is subject to the terms of the Mozilla
	// Public License v. 2.0. If a copy of the MPL was not distributed
	// with this file, You can obtain one at http://mozilla.org/MPL/2.0/.

	#include "main.h"

	#include <Eigen/CXX11/Tensor>

	using Eigen::DefaultDevice;
	using Eigen::Tensor;

	typedef Tensor<float, 1>::DimensionPair DimPair;

	template<int DataLayout>
	static void test_evals()
	{
	Tensor<float, 2, DataLayout> mat1(2, 3);
	Tensor<float, 2, DataLayout> mat2(2, 3);
	Tensor<float, 2, DataLayout> mat3(3, 2);

	mat1.setRandom();
	mat2.setRandom();
	mat3.setRandom();

	Tensor<float, 2, DataLayout> mat4(3,3);
	mat4.setZero();
	Eigen::array<DimPair, 1> dims3 = {{DimPair(0, 0)}};
	typedef TensorEvaluator<decltype(mat1.contract(mat2, dims3)), DefaultDevice> Evaluator;
	Evaluator eval(mat1.contract(mat2, dims3), DefaultDevice());
	eval.evalTo(mat4.data());
	EIGEN_STATIC_ASSERT(Evaluator::NumDims==2ul, YOU_MADE_A_PROGRAMMING_MISTAKE);
	VERIFY_IS_EQUAL(eval.dimensions()[0], 3);
	VERIFY_IS_EQUAL(eval.dimensions()[1], 3);

	VERIFY_IS_APPROX(mat4(0,0), mat1(0,0)mat2(0,0) + mat1(1,0)mat2(1,0));
	VERIFY_IS_APPROX(mat4(0,1), mat1(0,0)mat2(0,1) + mat1(1,0)mat2(1,1));
	VERIFY_IS_APPROX(mat4(0,2), mat1(0,0)mat2(0,2) + mat1(1,0)mat2(1,2));
	VERIFY_IS_APPROX(mat4(1,0), mat1(0,1)mat2(0,0) + mat1(1,1)mat2(1,0));
	VERIFY_IS_APPROX(mat4(1,1), mat1(0,1)mat2(0,1) + mat1(1,1)mat2(1,1));
	VERIFY_IS_APPROX(mat4(1,2), mat1(0,1)mat2(0,2) + mat1(1,1)mat2(1,2));
	VERIFY_IS_APPROX(mat4(2,0), mat1(0,2)mat2(0,0) + mat1(1,2)mat2(1,0));
	VERIFY_IS_APPROX(mat4(2,1), mat1(0,2)mat2(0,1) + mat1(1,2)mat2(1,1));
	VERIFY_IS_APPROX(mat4(2,2), mat1(0,2)mat2(0,2) + mat1(1,2)mat2(1,2));

	Tensor<float, 2, DataLayout> mat5(2,2);
	mat5.setZero();
	Eigen::array<DimPair, 1> dims4 = {{DimPair(1, 1)}};
	typedef TensorEvaluator<decltype(mat1.contract(mat2, dims4)), DefaultDevice> Evaluator2;
	Evaluator2 eval2(mat1.contract(mat2, dims4), DefaultDevice());
	eval2.evalTo(mat5.data());
	EIGEN_STATIC_ASSERT(Evaluator2::NumDims==2ul, YOU_MADE_A_PROGRAMMING_MISTAKE);
	VERIFY_IS_EQUAL(eval2.dimensions()[0], 2);
	VERIFY_IS_EQUAL(eval2.dimensions()[1], 2);

	VERIFY_IS_APPROX(mat5(0,0), mat1(0,0)mat2(0,0) + mat1(0,1)mat2(0,1) + mat1(0,2)*mat2(0,2));
	VERIFY_IS_APPROX(mat5(0,1), mat1(0,0)mat2(1,0) + mat1(0,1)mat2(1,1) + mat1(0,2)*mat2(1,2));
	VERIFY_IS_APPROX(mat5(1,0), mat1(1,0)mat2(0,0) + mat1(1,1)mat2(0,1) + mat1(1,2)*mat2(0,2));
	VERIFY_IS_APPROX(mat5(1,1), mat1(1,0)mat2(1,0) + mat1(1,1)mat2(1,1) + mat1(1,2)*mat2(1,2));

	Tensor<float, 2, DataLayout> mat6(2,2);
	mat6.setZero();
	Eigen::array<DimPair, 1> dims6 = {{DimPair(1, 0)}};
	typedef TensorEvaluator<decltype(mat1.contract(mat3, dims6)), DefaultDevice> Evaluator3;
	Evaluator3 eval3(mat1.contract(mat3, dims6), DefaultDevice());
	eval3.evalTo(mat6.data());
	EIGEN_STATIC_ASSERT(Evaluator3::NumDims==2ul, YOU_MADE_A_PROGRAMMING_MISTAKE);
	VERIFY_IS_EQUAL(eval3.dimensions()[0], 2);
	VERIFY_IS_EQUAL(eval3.dimensions()[1], 2);

	VERIFY_IS_APPROX(mat6(0,0), mat1(0,0)mat3(0,0) + mat1(0,1)mat3(1,0) + mat1(0,2)*mat3(2,0));
	VERIFY_IS_APPROX(mat6(0,1), mat1(0,0)mat3(0,1) + mat1(0,1)mat3(1,1) + mat1(0,2)*mat3(2,1));
	VERIFY_IS_APPROX(mat6(1,0), mat1(1,0)mat3(0,0) + mat1(1,1)mat3(1,0) + mat1(1,2)*mat3(2,0));
	VERIFY_IS_APPROX(mat6(1,1), mat1(1,0)mat3(0,1) + mat1(1,1)mat3(1,1) + mat1(1,2)*mat3(2,1));
	}

	template<int DataLayout>
	static void test_scalar()
	{
	Tensor<float, 1, DataLayout> vec1({6});
	Tensor<float, 1, DataLayout> vec2({6});

	vec1.setRandom();
	vec2.setRandom();

	Eigen::array<DimPair, 1> dims = {{DimPair(0, 0)}};
	Tensor<float, 0, DataLayout> scalar = vec1.contract(vec2, dims);

	float expected = 0.0f;
	for (int i = 0; i < 6; ++i) {
	expected += vec1(i) * vec2(i);
	}
	VERIFY_IS_APPROX(scalar(), expected);
	}

	template<int DataLayout>
	static void test_multidims()
	{
	Tensor<float, 3, DataLayout> mat1(2, 2, 2);
	Tensor<float, 4, DataLayout> mat2(2, 2, 2, 2);

	mat1.setRandom();
	mat2.setRandom();

	Tensor<float, 3, DataLayout> mat3(2, 2, 2);
	mat3.setZero();
	Eigen::array<DimPair, 2> dims = {{DimPair(1, 2), DimPair(2, 3)}};
	typedef TensorEvaluator<decltype(mat1.contract(mat2, dims)), DefaultDevice> Evaluator;
	Evaluator eval(mat1.contract(mat2, dims), DefaultDevice());
	eval.evalTo(mat3.data());
	EIGEN_STATIC_ASSERT(Evaluator::NumDims==3ul, YOU_MADE_A_PROGRAMMING_MISTAKE);
	VERIFY_IS_EQUAL(eval.dimensions()[0], 2);
	VERIFY_IS_EQUAL(eval.dimensions()[1], 2);
	VERIFY_IS_EQUAL(eval.dimensions()[2], 2);

	VERIFY_IS_APPROX(mat3(0,0,0), mat1(0,0,0)mat2(0,0,0,0) + mat1(0,1,0)mat2(0,0,1,0) +
	mat1(0,0,1)mat2(0,0,0,1) + mat1(0,1,1)mat2(0,0,1,1));
	VERIFY_IS_APPROX(mat3(0,0,1), mat1(0,0,0)mat2(0,1,0,0) + mat1(0,1,0)mat2(0,1,1,0) +
	mat1(0,0,1)mat2(0,1,0,1) + mat1(0,1,1)mat2(0,1,1,1));
	VERIFY_IS_APPROX(mat3(0,1,0), mat1(0,0,0)mat2(1,0,0,0) + mat1(0,1,0)mat2(1,0,1,0) +
	mat1(0,0,1)mat2(1,0,0,1) + mat1(0,1,1)mat2(1,0,1,1));
	VERIFY_IS_APPROX(mat3(0,1,1), mat1(0,0,0)mat2(1,1,0,0) + mat1(0,1,0)mat2(1,1,1,0) +
	mat1(0,0,1)mat2(1,1,0,1) + mat1(0,1,1)mat2(1,1,1,1));
	VERIFY_IS_APPROX(mat3(1,0,0), mat1(1,0,0)mat2(0,0,0,0) + mat1(1,1,0)mat2(0,0,1,0) +
	mat1(1,0,1)mat2(0,0,0,1) + mat1(1,1,1)mat2(0,0,1,1));
	VERIFY_IS_APPROX(mat3(1,0,1), mat1(1,0,0)mat2(0,1,0,0) + mat1(1,1,0)mat2(0,1,1,0) +
	mat1(1,0,1)mat2(0,1,0,1) + mat1(1,1,1)mat2(0,1,1,1));
	VERIFY_IS_APPROX(mat3(1,1,0), mat1(1,0,0)mat2(1,0,0,0) + mat1(1,1,0)mat2(1,0,1,0) +
	mat1(1,0,1)mat2(1,0,0,1) + mat1(1,1,1)mat2(1,0,1,1));
	VERIFY_IS_APPROX(mat3(1,1,1), mat1(1,0,0)mat2(1,1,0,0) + mat1(1,1,0)mat2(1,1,1,0) +
	mat1(1,0,1)mat2(1,1,0,1) + mat1(1,1,1)mat2(1,1,1,1));

	Tensor<float, 2, DataLayout> mat4(2, 2);
	Tensor<float, 3, DataLayout> mat5(2, 2, 2);

	mat4.setRandom();
	mat5.setRandom();

	Tensor<float, 1, DataLayout> mat6(2);
	mat6.setZero();
	Eigen::array<DimPair, 2> dims2({{DimPair(0, 1), DimPair(1, 0)}});
	typedef TensorEvaluator<decltype(mat4.contract(mat5, dims2)), DefaultDevice> Evaluator2;
	Evaluator2 eval2(mat4.contract(mat5, dims2), DefaultDevice());
	eval2.evalTo(mat6.data());
	EIGEN_STATIC_ASSERT(Evaluator2::NumDims==1ul, YOU_MADE_A_PROGRAMMING_MISTAKE);
	VERIFY_IS_EQUAL(eval2.dimensions()[0], 2);

	VERIFY_IS_APPROX(mat6(0), mat4(0,0)mat5(0,0,0) + mat4(1,0)mat5(0,1,0) +
	mat4(0,1)mat5(1,0,0) + mat4(1,1)mat5(1,1,0));
	VERIFY_IS_APPROX(mat6(1), mat4(0,0)mat5(0,0,1) + mat4(1,0)mat5(0,1,1) +
	mat4(0,1)mat5(1,0,1) + mat4(1,1)mat5(1,1,1));
	}

	template<int DataLayout>
	static void test_holes() {
	Tensor<float, 4, DataLayout> t1(2, 5, 7, 3);
	Tensor<float, 5, DataLayout> t2(2, 7, 11, 13, 3);
	t1.setRandom();
	t2.setRandom();

	Eigen::array<DimPair, 2> dims = {{DimPair(0, 0), DimPair(3, 4)}};
	Tensor<float, 5, DataLayout> result = t1.contract(t2, dims);
	VERIFY_IS_EQUAL(result.dimension(0), 5);
	VERIFY_IS_EQUAL(result.dimension(1), 7);
	VERIFY_IS_EQUAL(result.dimension(2), 7);
	VERIFY_IS_EQUAL(result.dimension(3), 11);
	VERIFY_IS_EQUAL(result.dimension(4), 13);

	for (int i = 0; i < 5; ++i) {
	for (int j = 0; j < 5; ++j) {
	for (int k = 0; k < 5; ++k) {
	for (int l = 0; l < 5; ++l) {
	for (int m = 0; m < 5; ++m) {
	VERIFY_IS_APPROX(result(i, j, k, l, m),
	t1(0, i, j, 0) * t2(0, k, l, m, 0) +
	t1(1, i, j, 0) * t2(1, k, l, m, 0) +
	t1(0, i, j, 1) * t2(0, k, l, m, 1) +
	t1(1, i, j, 1) * t2(1, k, l, m, 1) +
	t1(0, i, j, 2) * t2(0, k, l, m, 2) +
	t1(1, i, j, 2) * t2(1, k, l, m, 2));
	}
	}
	}
	}
	}
	}

	template<int DataLayout>
	static void test_full_redux()
	{
	Tensor<float, 2, DataLayout> t1(2, 2);
	Tensor<float, 3, DataLayout> t2(2, 2, 2);
	t1.setRandom();
	t2.setRandom();

	Eigen::array<DimPair, 2> dims = {{DimPair(0, 0), DimPair(1, 1)}};
	Tensor<float, 1, DataLayout> result = t1.contract(t2, dims);
	VERIFY_IS_EQUAL(result.dimension(0), 2);
	VERIFY_IS_APPROX(result(0), t1(0, 0) * t2(0, 0, 0) + t1(1, 0) * t2(1, 0, 0)
	+ t1(0, 1) * t2(0, 1, 0) + t1(1, 1) * t2(1, 1, 0));
	VERIFY_IS_APPROX(result(1), t1(0, 0) * t2(0, 0, 1) + t1(1, 0) * t2(1, 0, 1)
	+ t1(0, 1) * t2(0, 1, 1) + t1(1, 1) * t2(1, 1, 1));

	dims[0] = DimPair(1, 0);
	dims[1] = DimPair(2, 1);
	result = t2.contract(t1, dims);
	VERIFY_IS_EQUAL(result.dimension(0), 2);
	VERIFY_IS_APPROX(result(0), t1(0, 0) * t2(0, 0, 0) + t1(1, 0) * t2(0, 1, 0)
	+ t1(0, 1) * t2(0, 0, 1) + t1(1, 1) * t2(0, 1, 1));
	VERIFY_IS_APPROX(result(1), t1(0, 0) * t2(1, 0, 0) + t1(1, 0) * t2(1, 1, 0)
	+ t1(0, 1) * t2(1, 0, 1) + t1(1, 1) * t2(1, 1, 1));
	}

	template<int DataLayout>
	static void test_contraction_of_contraction()
	{
	Tensor<float, 2, DataLayout> t1(2, 2);
	Tensor<float, 2, DataLayout> t2(2, 2);
	Tensor<float, 2, DataLayout> t3(2, 2);
	Tensor<float, 2, DataLayout> t4(2, 2);
	t1.setRandom();
	t2.setRandom();
	t3.setRandom();
	t4.setRandom();

	Eigen::array<DimPair, 1> dims = {{DimPair(1, 0)}};
	auto contract1 = t1.contract(t2, dims);
	auto diff = t3 - contract1;
	auto contract2 = t1.contract(t4, dims);
	Tensor<float, 2, DataLayout> result = contract2.contract(diff, dims);

	VERIFY_IS_EQUAL(result.dimension(0), 2);
	VERIFY_IS_EQUAL(result.dimension(1), 2);

	Eigen::Map<Eigen::Matrix<float, Dynamic, Dynamic, DataLayout>>
	m1(t1.data(), 2, 2), m2(t2.data(), 2, 2), m3(t3.data(), 2, 2),
	m4(t4.data(), 2, 2);
	Eigen::Matrix<float, Dynamic, Dynamic, DataLayout>
	expected = (m1 * m4) * (m3 - m1 * m2);

	VERIFY_IS_APPROX(result(0, 0), expected(0, 0));
	VERIFY_IS_APPROX(result(0, 1), expected(0, 1));
	VERIFY_IS_APPROX(result(1, 0), expected(1, 0));
	VERIFY_IS_APPROX(result(1, 1), expected(1, 1));
	}

	template<int DataLayout>
	static void test_expr()
	{
	Tensor<float, 2, DataLayout> mat1(2, 3);
	Tensor<float, 2, DataLayout> mat2(3, 2);
	mat1.setRandom();
	mat2.setRandom();

	Tensor<float, 2, DataLayout> mat3(2,2);

	Eigen::array<DimPair, 1> dims = {{DimPair(1, 0)}};
	mat3 = mat1.contract(mat2, dims);

	VERIFY_IS_APPROX(mat3(0,0), mat1(0,0)mat2(0,0) + mat1(0,1)mat2(1,0) + mat1(0,2)*mat2(2,0));
	VERIFY_IS_APPROX(mat3(0,1), mat1(0,0)mat2(0,1) + mat1(0,1)mat2(1,1) + mat1(0,2)*mat2(2,1));
	VERIFY_IS_APPROX(mat3(1,0), mat1(1,0)mat2(0,0) + mat1(1,1)mat2(1,0) + mat1(1,2)*mat2(2,0));
	VERIFY_IS_APPROX(mat3(1,1), mat1(1,0)mat2(0,1) + mat1(1,1)mat2(1,1) + mat1(1,2)*mat2(2,1));
	}

	template<int DataLayout>
	static void test_out_of_order_contraction()
	{
	Tensor<float, 3, DataLayout> mat1(2, 2, 2);
	Tensor<float, 3, DataLayout> mat2(2, 2, 2);

	mat1.setRandom();
	mat2.setRandom();

	Tensor<float, 2, DataLayout> mat3(2, 2);

	Eigen::array<DimPair, 2> dims = {{DimPair(2, 0), DimPair(0, 2)}};
	mat3 = mat1.contract(mat2, dims);

	VERIFY_IS_APPROX(mat3(0, 0),
	mat1(0,0,0)mat2(0,0,0) + mat1(1,0,0)mat2(0,0,1) +
	mat1(0,0,1)mat2(1,0,0) + mat1(1,0,1)mat2(1,0,1));
	VERIFY_IS_APPROX(mat3(1, 0),
	mat1(0,1,0)mat2(0,0,0) + mat1(1,1,0)mat2(0,0,1) +
	mat1(0,1,1)mat2(1,0,0) + mat1(1,1,1)mat2(1,0,1));
	VERIFY_IS_APPROX(mat3(0, 1),
	mat1(0,0,0)mat2(0,1,0) + mat1(1,0,0)mat2(0,1,1) +
	mat1(0,0,1)mat2(1,1,0) + mat1(1,0,1)mat2(1,1,1));
	VERIFY_IS_APPROX(mat3(1, 1),
	mat1(0,1,0)mat2(0,1,0) + mat1(1,1,0)mat2(0,1,1) +
	mat1(0,1,1)mat2(1,1,0) + mat1(1,1,1)mat2(1,1,1));

	Eigen::array<DimPair, 2> dims2 = {{DimPair(0, 2), DimPair(2, 0)}};
	mat3 = mat1.contract(mat2, dims2);

	VERIFY_IS_APPROX(mat3(0, 0),
	mat1(0,0,0)mat2(0,0,0) + mat1(1,0,0)mat2(0,0,1) +
	mat1(0,0,1)mat2(1,0,0) + mat1(1,0,1)mat2(1,0,1));
	VERIFY_IS_APPROX(mat3(1, 0),
	mat1(0,1,0)mat2(0,0,0) + mat1(1,1,0)mat2(0,0,1) +
	mat1(0,1,1)mat2(1,0,0) + mat1(1,1,1)mat2(1,0,1));
	VERIFY_IS_APPROX(mat3(0, 1),
	mat1(0,0,0)mat2(0,1,0) + mat1(1,0,0)mat2(0,1,1) +
	mat1(0,0,1)mat2(1,1,0) + mat1(1,0,1)mat2(1,1,1));
	VERIFY_IS_APPROX(mat3(1, 1),
	mat1(0,1,0)mat2(0,1,0) + mat1(1,1,0)mat2(0,1,1) +
	mat1(0,1,1)mat2(1,1,0) + mat1(1,1,1)mat2(1,1,1));

	}

	template<int DataLayout>
	static void test_consistency()
	{
	// this does something like testing (AB)^T = (B^T A^T)

	Tensor<float, 3, DataLayout> mat1(4, 3, 5);
	Tensor<float, 5, DataLayout> mat2(3, 2, 1, 5, 4);
	mat1.setRandom();
	mat2.setRandom();

	Tensor<float, 4, DataLayout> mat3(5, 2, 1, 5);
	Tensor<float, 4, DataLayout> mat4(2, 1, 5, 5);

	// contract on dimensions of size 4 and 3
	Eigen::array<DimPair, 2> dims1 = {{DimPair(0, 4), DimPair(1, 0)}};
	Eigen::array<DimPair, 2> dims2 = {{DimPair(4, 0), DimPair(0, 1)}};

	mat3 = mat1.contract(mat2, dims1);
	mat4 = mat2.contract(mat1, dims2);

	// check that these are equal except for ordering of dimensions
	if (DataLayout == ColMajor) {
	for (size_t i = 0; i < 5; i++) {
	for (size_t j = 0; j < 10; j++) {
	VERIFY_IS_APPROX(mat3.data()[i + 5 * j], mat4.data()[j + 10 * i]);
	}
	}
	} else {
	// Row major
	for (size_t i = 0; i < 5; i++) {
	for (size_t j = 0; j < 10; j++) {
	VERIFY_IS_APPROX(mat3.data()[10 * i + j], mat4.data()[i + 5 * j]);
	}
	}
	}
	}

	template<int DataLayout>
	static void test_large_contraction()
	{
	Tensor<float, 4, DataLayout> t_left(30, 50, 8, 31);
	Tensor<float, 5, DataLayout> t_right(8, 31, 7, 20, 10);
	Tensor<float, 5, DataLayout> t_result(30, 50, 7, 20, 10);

	t_left.setRandom();
	t_right.setRandom();

	// Add a little offset so that the results won't be close to zero.
	t_left += t_left.constant(1.0f);
	t_right += t_right.constant(1.0f);

	typedef Map<Eigen::Matrix<float, Dynamic, Dynamic, DataLayout>> MapXf;
	MapXf m_left(t_left.data(), 1500, 248);
	MapXf m_right(t_right.data(), 248, 1400);
	Eigen::Matrix<float, Dynamic, Dynamic, DataLayout> m_result(1500, 1400);

	// this contraction should be equivalent to a single matrix multiplication
	Eigen::array<DimPair, 2> dims = {{DimPair(2, 0), DimPair(3, 1)}};

	// compute results by separate methods
	t_result = t_left.contract(t_right, dims);
	m_result = m_left * m_right;

	for (int i = 0; i < t_result.dimensions().TotalSize(); i++) {
	VERIFY(&t_result.data()[i] != &m_result.data()[i]);
	VERIFY_IS_APPROX(t_result.data()[i], m_result.data()[i]);
	}
	}

	template<int DataLayout>
	static void test_matrix_vector()
	{
	Tensor<float, 2, DataLayout> t_left(30, 50);
	Tensor<float, 1, DataLayout> t_right(50);
	Tensor<float, 1, DataLayout> t_result(30);

	t_left.setRandom();
	t_right.setRandom();

	typedef Map<Eigen::Matrix<float, Dynamic, Dynamic, DataLayout>> MapXf;
	MapXf m_left(t_left.data(), 30, 50);
	MapXf m_right(t_right.data(), 50, 1);
	Eigen::Matrix<float, Dynamic, Dynamic, DataLayout> m_result(30, 1);

	// this contraction should be equivalent to a single matrix multiplication
	Eigen::array<DimPair, 1> dims{{DimPair(1, 0)}};

	// compute results by separate methods
	t_result = t_left.contract(t_right, dims);
	m_result = m_left * m_right;

	for (int i = 0; i < t_result.dimensions().TotalSize(); i++) {
	VERIFY(internal::isApprox(t_result(i), m_result(i, 0), 1));
	}
	}


	template<int DataLayout>
	static void test_tensor_vector()
	{
	Tensor<float, 3, DataLayout> t_left(7, 13, 17);
	Tensor<float, 2, DataLayout> t_right(1, 7);

	t_left.setRandom();
	t_right.setRandom();

	typedef typename Tensor<float, 1, DataLayout>::DimensionPair DimensionPair;
	Eigen::array<DimensionPair, 1> dim_pair01{{{0, 1}}};
	Tensor<float, 3, DataLayout> t_result = t_left.contract(t_right, dim_pair01);

	typedef Map<Eigen::Matrix<float, Dynamic, Dynamic, DataLayout>> MapXf;
	MapXf m_left(t_left.data(), 7, 13*17);
	MapXf m_right(t_right.data(), 1, 7);
	Eigen::Matrix<float, Dynamic, Dynamic, DataLayout> m_result = m_left.transpose() * m_right.transpose();

	for (int i = 0; i < t_result.dimensions().TotalSize(); i++) {
	VERIFY(internal::isApprox(t_result(i), m_result(i, 0), 1));
	}
	}


	template<int DataLayout>
	static void test_small_blocking_factors()
	{
	Tensor<float, 4, DataLayout> t_left(30, 5, 3, 31);
	Tensor<float, 5, DataLayout> t_right(3, 31, 7, 20, 1);
	t_left.setRandom();
	t_right.setRandom();

	// Add a little offset so that the results won't be close to zero.
	t_left += t_left.constant(1.0f);
	t_right += t_right.constant(1.0f);

	// Force the cache sizes, which results in smaller blocking factors.
	Eigen::setCpuCacheSizes(896, 1920, 2944);

	// this contraction should be equivalent to a single matrix multiplication
	Eigen::array<DimPair, 2> dims = {{DimPair(2, 0), DimPair(3, 1)}};
	Tensor<float, 5, DataLayout> t_result;
	t_result = t_left.contract(t_right, dims);

	// compute result using a simple eigen matrix product
	Map<Eigen::Matrix<float, Dynamic, Dynamic, DataLayout>> m_left(t_left.data(), 150, 93);
	Map<Eigen::Matrix<float, Dynamic, Dynamic, DataLayout>> m_right(t_right.data(), 93, 140);
	Eigen::Matrix<float, Dynamic, Dynamic, DataLayout> m_result = m_left * m_right;

	for (int i = 0; i < t_result.dimensions().TotalSize(); i++) {
	VERIFY_IS_APPROX(t_result.data()[i], m_result.data()[i]);
	}
	}

	template<int DataLayout>
	static void test_tensor_product()
	{
	Tensor<float, 2, DataLayout> mat1(2, 3);
	Tensor<float, 2, DataLayout> mat2(4, 1);
	mat1.setRandom();
	mat2.setRandom();

	Tensor<float, 4, DataLayout> result = mat1.contract(mat2, Eigen::array<DimPair, 0>{{}});

	VERIFY_IS_EQUAL(result.dimension(0), 2);
	VERIFY_IS_EQUAL(result.dimension(1), 3);
	VERIFY_IS_EQUAL(result.dimension(2), 4);
	VERIFY_IS_EQUAL(result.dimension(3), 1);
	for (int i = 0; i < result.dimension(0); ++i) {
	for (int j = 0; j < result.dimension(1); ++j) {
	for (int k = 0; k < result.dimension(2); ++k) {
	for (int l = 0; l < result.dimension(3); ++l) {
	VERIFY_IS_APPROX(result(i, j, k, l), mat1(i, j) * mat2(k, l) );
	}
	}
	}
	}
	}


	template<int DataLayout>
	static void test_const_inputs()
	{
	Tensor<float, 2, DataLayout> in1(2, 3);
	Tensor<float, 2, DataLayout> in2(3, 2);
	in1.setRandom();
	in2.setRandom();

	TensorMap<Tensor<const float, 2, DataLayout> > mat1(in1.data(), 2, 3);
	TensorMap<Tensor<const float, 2, DataLayout> > mat2(in2.data(), 3, 2);
	Tensor<float, 2, DataLayout> mat3(2,2);

	Eigen::array<DimPair, 1> dims = {{DimPair(1, 0)}};
	mat3 = mat1.contract(mat2, dims);

	VERIFY_IS_APPROX(mat3(0,0), mat1(0,0)mat2(0,0) + mat1(0,1)mat2(1,0) + mat1(0,2)*mat2(2,0));
	VERIFY_IS_APPROX(mat3(0,1), mat1(0,0)mat2(0,1) + mat1(0,1)mat2(1,1) + mat1(0,2)*mat2(2,1));
	VERIFY_IS_APPROX(mat3(1,0), mat1(1,0)mat2(0,0) + mat1(1,1)mat2(1,0) + mat1(1,2)*mat2(2,0));
	VERIFY_IS_APPROX(mat3(1,1), mat1(1,0)mat2(0,1) + mat1(1,1)mat2(1,1) + mat1(1,2)*mat2(2,1));
	}

	void test_cxx11_tensor_contraction()
	{
	CALL_SUBTEST(test_evals<ColMajor>());
	CALL_SUBTEST(test_evals<RowMajor>());
	CALL_SUBTEST(test_scalar<ColMajor>());
	CALL_SUBTEST(test_scalar<RowMajor>());
	CALL_SUBTEST(test_multidims<ColMajor>());
	CALL_SUBTEST(test_multidims<RowMajor>());
	CALL_SUBTEST(test_holes<ColMajor>());
	CALL_SUBTEST(test_holes<RowMajor>());
	CALL_SUBTEST(test_full_redux<ColMajor>());
	CALL_SUBTEST(test_full_redux<RowMajor>());
	CALL_SUBTEST(test_contraction_of_contraction<ColMajor>());
	CALL_SUBTEST(test_contraction_of_contraction<RowMajor>());
	CALL_SUBTEST(test_expr<ColMajor>());
	CALL_SUBTEST(test_expr<RowMajor>());
	CALL_SUBTEST(test_out_of_order_contraction<ColMajor>());
	CALL_SUBTEST(test_out_of_order_contraction<RowMajor>());
	CALL_SUBTEST(test_consistency<ColMajor>());
	CALL_SUBTEST(test_consistency<RowMajor>());
	CALL_SUBTEST(test_large_contraction<ColMajor>());
	CALL_SUBTEST(test_large_contraction<RowMajor>());
	CALL_SUBTEST(test_matrix_vector<ColMajor>());
	CALL_SUBTEST(test_matrix_vector<RowMajor>());
	CALL_SUBTEST(test_tensor_vector<ColMajor>());
	CALL_SUBTEST(test_tensor_vector<RowMajor>());
	CALL_SUBTEST(test_small_blocking_factors<ColMajor>());
	CALL_SUBTEST(test_small_blocking_factors<RowMajor>());
	CALL_SUBTEST(test_tensor_product<ColMajor>());
	CALL_SUBTEST(test_tensor_product<RowMajor>());
	CALL_SUBTEST(test_const_inputs<ColMajor>());
	CALL_SUBTEST(test_const_inputs<RowMajor>());
	}